Oligomers

ABSTRACT

Certain disclosed oligomers induce exon skipping during processing of myostatin pre-mRNA. The oligomers may be in a vector or encoded by the vector. The vector is used for inducing exon skipping during processing of myostatin pre-mRNA. A therapeutically effective amount of the oligomer may be administered to a subject patient such that exon skipping during processing of myostatin pre-mRNA is induced. The administration to a subject may be used in order to increase or maintain muscle mass, or slowing degeneration of muscle mass in the subject. The administration to a subject may ameliorate muscle wasting conditions, such as muscular dystrophy. Examples of such muscular dystrophies which may be so treated include Becker&#39;s muscular dystrophy, congenital muscular dystrophy, Duchenne muscular dystrophy, distal muscular dystrophy, Emery-Dreifuss muscular dystrophy, facioscapulohumeral muscular dystrophy (FSHD), limb-girdle muscular dystrophy, myotonic muscular dystrophy, and oculopharyngeal muscular dystrophy.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 15/078,029 filed on Mar. 23, 2016, entitled “OLIGOMERS”, which is a divisional application of U.S. application Ser. No. 14/504,453 filed on Oct. 2, 2014, entitled “OLIGOMERS”, which is a continuation of U.S. patent application Ser. No. 13/644,363 filed on Oct. 4, 2012, entitled “OLIGOMERS”, which claims priority to U.S. Provisional Patent Application No. 61/543,145 filed on Oct. 4, 2011 entitled “OLIGOMERS”, the disclosures of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to oligomers which are capable of causing exon skipping and, in particular, relates to oligomers which are capable of causing exon skipping in the myostatin gene.

BACKGROUND TO THE INVENTION

A range of strategies have been proposed to enhance muscle bulk and strength as a treatment for a number of age-related muscle disorders and various neuromuscular disorders, including muscular dystrophies. Myostatin, a transforming growth factor-β family member, also called growth and differentiation factor-8, is a negative regulator of muscle growth and the myostatin signalling axis has been a major focus in such strategies. Myostatin null or hypomorphic animals are significantly larger than wild-type animals and show a large increase in skeletal muscle mass.¹ The first natural myostatin mutation in humans has also been identified in a young boy.² Myostatin blockade, therefore, offers a strategy for counteracting muscle-wasting conditions including Duchenne muscular dystrophy.³ Delivery of myostatin-inhibiting genes, including growth and differentiation factor-associated serum protein-1 (GASP-1), follistatin-related gene (FLRG), follistatin-344 (FS) and myostatin propeptide, via adeno-associated virus,⁴⁻⁶ lead to an increase in muscle mass in treated animals, with the greatest increase in FS-treated animals.⁷ Use of potentially therapeutic antimyostatin-blocking antibodies of high-binding affinity has proved to be a promising strategy. However, there are some constraints related to the use of antimyostatin antibodies that include difficulty in long-term sustainability, undesirable immune responses, and inhibitory effects not precisely specific to myostatin in regard to muscle growth.^(8,9) Significant increase in skeletal muscle mass was also observed using adeno-associated virus vectors to deliver a recombinant myostatin propeptide gene fragment, or by a retrovirus-based RNA interference system (RNAi).^(4,6,10) Both approaches have safety concerns of possible genotoxicity, due to uncontrolled vector genome insertion into host chromosomes.¹¹ The RNAi system faces an additional hurdle in terms of effective delivery of the RNAi molecules into the disease models for clinical studies.¹² RNA-based modulation therapy has the potential to overcome difficulties encountered by conventional gene therapy methods. Antisense oligonucleotides (AOs) are capable of hybridizing to a sense target sequence leading to cleavage of the RNA:DNA hybrid by RNase H which results in downregulation of gene transcription.^(13,14) In an alternative approach, antisense-mediated modulation of pre-mRNA splicing has been pioneered by Dominski and Kole.¹⁵ In the first experiments, AOs were aimed at activated cryptic splice sites in the β-globin (HBB) and cystic fibrosis transmembrane conductance regulator (CFTR) genes in order to restore normal splicing in β-thalassemia and cystic fibrosis patients.¹⁵⁻¹⁷ The identification of exon/intron boundaries by the splicing machinery, and therefore inclusion of the exons into the mRNA, is extensively thought to depend on exonic splicing enhancer (ESE) motifs.¹⁸ By masking these ESE sites with sequence-optimized AOs, the targeted exons are no longer recognized as exons, and are spliced out with neighbouring introns. This so-called antisense-induced exon skipping has already been used clinically to partly correct the mutated dystrophin and convert the severe Duchenne muscular dystrophy phenotype into a milder Becker muscular dystrophy phenotype.¹⁹ Clinical trials to determine the safety profile and the efficacy of single intramuscular doses of two different chemistries of AOs, 2′-O-methyl phosphorothioate (2′OMePS) AOs and phosphorodiamidate morpholino oligomers (PMOs) in Duchenne muscular dystrophy patients have recently been completed.^(20,21) The treatments were well tolerated by all the patients and the injection of AOs induced the production of dystrophin. 2′OMePS AOs, being negatively charged, are easily delivered in vitro, whereas PMOs are capable of more sustained effect in vivo due to their resistance to enzymatic degradation²² and owing to their longer sequence, have increased affinity to target.²³ When conjugated with various peptide derivatives, or with dendrimeric octa-guanidine (so-called Vivo-morpholino), PMOs demonstrate a significantly increased delivery in the case of dystrophin skipping.^(24,25)

SUMMARY OF THE INVENTION

The inventors have adopted the approach of using AOs with different chemistries, so enhancing their half-lives relative to RNAi molecules, to investigate the outcome of myostatin knockdown by exon skipping. Skipping of exon 2 (374 nucleotides) of myostatin leads to an out-of-phase splicing of exons 1 and 3, and knockdown of myostatin due to truncation of the Open Reading Frame and nonsense-mediated mRNA decay. The data present here constitute a proof-of-principle that oligonucleotide-mediated antisense exon skipping leads to a physiologically significant myostatin knockdown in vitro and in vivo. This type of antisense treatment could thus form part of an effective strategy to improve various muscle-wasting conditions, and along with dystrophin rescue or augmentation, to treat Duchenne muscular dystrophy.

The present invention relates to oligomers which can bind to pre-mRNA produced from the myostatin gene and cause exon skipping during cellular processing of the pre-mRNA.

The present invention provides an oligomer for inducing exon skipping during processing of myostatin pre-mRNA, the oligomer comprising at least 20 contiguous bases of a base sequence selected from the group consisting of:

 1) XCXCGACGGGXCXCAAAXAXAXCCAXAGXX; (SEQ ID NO. 1)  2) XGXACCGXCXXXCAXAGGXXXGAXGAGXCX; (SEQ ID NO. 2)  3) CCXGGGXXCAXGXCAAGXXXCAGAGAXCGG; (SEQ ID NO. 3)  4) CAGCCCAXCXXCXCCXGGXCCXGGGAAGGX; (SEQ ID NO. 4)  5) XCXXGACGGGXCXGAGAXAXAXCCACAGXX; (SEQ ID NO. 5)  6) XGXACCGXCXXXCAXGGGXXXGAXGAGXCX; (SEQ ID NO. 6)  7) CCXGGGCXCAXGXCAAGXXXCAGAGAXCGG; (SEQ ID NO. 7)  8) XCCACAGXXGGGCXXXXACX; (SEQ ID NO. 8)  9) XCXGAGAXAXAXCCACAGXX; (SEQ ID NO. 9) 10) XCXXGACGGGXCXGAGAXAX; (SEQ ID NO. 10) 11) XGAXGAGXCXCAGGAXXXGC; (SEQ ID NO. 11) 12) XXCAXGGGXXXGAXGAGXCX; (SEQ ID NO. 12) 13) XXGXACCGXCXXXCAXGGGX; (SEQ ID NO. 13) 14) CAGAGAXCGGAXXCCAGXAX; (SEQ ID NO. 14) 15) XGXCAAGXXXCAGAGAXCGG; (SEQ ID NO. 15) 16) CCXGGGCXCAXGXCAAGXXX; (SEQ ID NO. 16) 17) CXGGGAAGGXXACAGCAAGA; (SEQ ID NO. 17) 18) XCXCCXGGXCCXGGGAAGGX; (SEQ ID NO. 18) and 19) CAGCCCAXCXXCXCCXGGXC, (SEQ ID NO. 19) wherein X is T or U and the oligomer's base sequence can vary from the above sequence at up to two base positions, and wherein the oligomer can bind to a target site in the myostatin pre-mRNA to cause exon skipping.

The oligomers described above cause exon skipping in the myostatin gene. In particular, these oligomers cause exon skipping of exon two of the myostatin gene, i.e. when the myostatin pre-mRNA is processed into mRNA, the oligomers stop exon two from being included in the mRNA.

Without being restricted to any particular theory, it is thought that the binding of the oligomers to the myostatin pre-mRNA interacts with or interferes with the binding of SR proteins to the exon. SR proteins are involved in the splicing process of adjacent exons. Therefore, it is thought that interacting or interfering with the binding of the SR proteins interferes with the splicing machinery resulting in exon skipping.

The base “X” in the above base sequences is defined as being thymine (T) or uracil (U). The presence of either base in the sequence will still allow the oligomer to bind to the pre-mRNA of the myostatin gene as it is a complementary sequence. Therefore, the presence of either base in the oligomer will cause exon skipping. The base sequence of the oligomer may contain all thymines, all uracils or a combination of the two. One factor that can determine whether X is T or U is the chemistry used to produce the oligomer. For example, if the oligomer is a phosphorodiamidate morpholino oligonucleotide (PMO), X will be T as this base is used when producing PMOs. Alternatively, if the oligomer is a phosphorothioate-linked 2′-O-methyl oligonucleotide (2′OMePS), X will be U as this base is used when producing 2′OMePSs. Preferably, the base “X” is only thymine (T).

The advantage provided by the oligomer is that it causes exon skipping. Preferably, the oligomer causes an exon skipping rate of at least 40%, i.e. exon two will be skipped 40% of the time. More preferably, the oligomer causes an exon skipping rate of at least 50%, more preferably still, at least 60%, even more preferably, at least 70%, more preferably still, at least 75%, more preferably, at least 80%, even more preferably, at least 85%, more preferably still, at least 90%, even most preferably, at least 95%, more preferably, at least 98% and even more preferably, at least about 99%. Exon skipping can be measured by transfection (leashed or unleashed: concentration between 50 and 500 nM) into cultured human myoblast cells (e.g., using a transfection reagent such as Lipofectamine2000™), and evaluation of skipped and unskipped mRNAs by electrophoretic densitometric analysis of RTPCR reaction products.

The oligomer can be any type of oligomer as long as it has the selected base sequence and can bind to a target site of the myostatin pre-mRNA to cause exon skipping. For example, the oligomer can be an oligodeoxyribonucleotide, an oligoribonucleotide, a phosphorodiamidate morpholino oligonucleotide (PMO) or a phosphorothioate-linked 2′-O-methyl oligonucleotide (2′OMePS). Preferably, the oligomer is a PMO or a 2′OMePS. In one embodiment, the oligomer is a PMO. The advantage of a PMO is that it has excellent safety profiles and appears to have longer lasting effects in vivo compared to 2′OMePS oligonucleotides. Preferably, the oligomer is isolated so that it is free from other compounds or contaminants.

The base sequence of the oligomer can vary from the selected sequence at up to two base positions. If the base sequence does vary at two positions, the oligomer will still be able to bind to the myostatin pre-mRNA to cause exon skipping. Preferably, the base sequence of the oligomer varies from the selected sequence at up to one base position and, more preferably, the base sequence does not vary from the selected sequence. The less that the base sequence of the oligomer varies from the selected sequence, the more efficiently it binds to the target site in order to cause exon skipping.

The oligomer is at least 20 bases in length. Preferably, the oligomer is at least 25 bases in length. In some embodiments, the oligomer may be at least 28 bases in length or at least 30 bases in length. Preferably, the oligomer is no more than 40 bases in length. In some embodiments, the oligomer may be no more than 35 bases in length or no more than 32 bases in length. Preferably, the oligomer is between 20 and 40 bases in length. More preferably, the oligomer is between 25 and 35 bases in length. In some embodiments, the oligomer is between 28 and 32 bases in length, between 29 and 31 bases in length, or about 30 bases in length. It has been found that an oligomer which is 30 bases in length causes efficient exon skipping. If the oligomer is longer than 40 bases in length, the specificity of the binding to the target site may be reduced. If the oligomer is less than 20 bases in length, the exon skipping efficiency may be reduced.

In some embodiments, the oligomer comprises at least 20 contiguous bases of a base sequence selected from the group consisting of SEQ ID NOS. 1-7, wherein the oligomer's base sequence can vary from SEQ ID NOS. 1-7 at up to two base positions.

In other embodiments, the oligomer comprises at least 20 contiguous bases of a base sequence selected from the group consisting of SEQ ID NOS. 1-4, wherein the oligomer's base sequence can vary from SEQ ID NOS. 1-4 at up to two base positions.

In the above embodiments relating to SEQ ID NOS. 1-7 and SEQ ID NOS. 1-4, the oligomer preferably comprises at least 25 contiguous bases of the base sequences. More preferably, the oligomer comprises at least 28 contiguous bases of the base sequences. In some embodiments, the oligomer comprises 30 contiguous bases of the base sequences, i.e. the oligomer comprises the base sequences of SEQ ID NOS. 1-7 or SEQ ID NOS. 1-4. In the embodiments described in this paragraph, the oligomer's base sequence can still vary from SEQ ID NOS. 1-7 or SEQ ID NOS. 1-4 at up to two base positions.

The oligomer may be conjugated to or complexed with various distinct chemical entities. For example, the oligomer may be conjugated to or complexed with a targeting protein in order to target the oligomer to, for example, muscle tissue. If the oligomer is conjugated to an entity, it may be conjugated directly or via a linker. In one embodiment, a plurality of oligomers may be conjugated to or complexed with a single entity. For example, the oligomer may be conjugated to octa-guanidine dendrimers. Alternatively, an arginine-rich cell penetrating peptide (CPP) can be conjugated to or complexed with the oligomer. In particular, (R-Ahx-R)₄AhxB can be used, where Ahx is 6-aminohexanoic acid and B is beta-alanine (Moulton H M et al. (2007) Biochem. Soc. Trans. 35: 826-8.), or alternatively (RXRRBR)₂XB (SEQ ID NO: 36) can be used.²⁶ These entities have been complexed to known dystrophin exon-skipping oligomers which have shown sustained skipping of dystrophin exons in vitro and in vivo.

Alternatively, a range of nanoparticle systems can be used to deliver the oligomers⁷⁴.

In another aspect, the present invention provides a vector for inducing exon skipping during processing of myostatin pre-mRNA, the vector encoding an oligomer of the invention, wherein when the vector is introduced into a cell (e.g. a human cell), the oligomer is expressed. For example, it is possible to express antisense sequences in the form of a gene, which can thus be delivered on a vector. One way to do this would be to modify the sequence of a U7 snRNA gene to include an antisense sequence according to the invention. The U7 gene, complete with its own promoter sequences, can be delivered on an adeno-associated virus (AAV) vector, to induce bodywide exon skipping. Similar methods to achieve exon skipping, by using a vector encoding an oligomer of the invention, would be apparent to one skilled in the art.

The present invention also provides a pharmaceutical composition for inducing exon skipping during processing of myostatin pre-mRNA, the composition comprising an oligomer as described above or a vector as described above and a pharmaceutically acceptable carrier, adjuvant or vehicle.

Pharmaceutical compositions of this invention comprise an oligomer of the present invention, and pharmaceutically acceptable salts, esters, salts of such esters, or any other compound which, upon administration to a subject (e.g. a human), is capable of providing (directly or indirectly) the biologically active oligomer thereof, with a pharmaceutically acceptable carrier, adjuvant or vehicle. Pharmaceutically acceptable carriers, adjuvants and vehicles that may be used in the pharmaceutical compositions of this invention include, but are not limited to, ion exchangers, alumina, aluminum stearate, lecithin, serum proteins, such as human serum albumin, buffer substances such as phosphates, glycine, sorbic acid, potassium sorbate, partial glyceride mixtures of saturated vegetable fatty acids, water, salts or electrolytes, such as protamine sulfate, disodium hydrogen phosphate, potassium hydrogen phosphate, sodium chloride, zinc salts, colloidal silica, magnesium trisilicate, polyvinyl pyrrolidone, cellulose-based substances, polyethylene glycol, sodium carboxymethylcellulose, polyacrylates, waxes, polyethylene-polyoxypropylene-block polymers, polyethylene glycol and wool fat.

The pharmaceutical compositions of this invention may be administered orally, parenterally, by inhalation spray, topically, rectally, nasally, buccally, vaginally, intradermally or via an implanted reservoir. Oral administration or administration by injection is preferred. The pharmaceutical compositions of this invention may contain any conventional non-toxic pharmaceutically-acceptable carriers, adjuvants or vehicles. The term parenteral as used herein includes subcutaneous, intracutaneous, intravenous, intramuscular, intra-articular, intrasynovial, intrasternal, intrathecal, intralesional and intracranial injection or infusion techniques. Preferably, the route of administration is by injection, more preferably, the route of administration is intramuscular, intravenous or subcutaneous injection and most preferably, the route of administration is intravenous or intramuscular injection.

The pharmaceutical compositions may be in the form of a sterile injectable preparation, for example, as a sterile injectable aqueous or oleaginous suspension. This suspension may be formulated according to techniques known in the art using suitable dispersing or wetting agents (such as, for example, Tween 80) and suspending agents. The sterile injectable preparation may also be a sterile injectable solution or suspension in a non-toxic parenterally-acceptable diluent or solvent, for example, as a solution in 1,3-butanediol. Among the acceptable vehicles and solvents that may be employed are mannitol, water, Ringer's solution and isotonic sodium chloride solution. In addition, sterile, fixed oils are conventionally employed as a solvent or suspending medium. For this purpose, any bland fixed oil may be employed including synthetic mono- or diglycerides. Fatty acids, such as oleic acid and its glyceride derivatives are useful in the preparation of injectables, as are natural pharmaceutically acceptable oils, such as olive oil or castor oil, especially in their polyoxyethylated versions. These oil solutions or suspensions may also contain a long-chain alcohol diluent, dispersant or similar alcohol.

The pharmaceutical compositions of this invention may be orally administered in any orally acceptable dosage form including, but not limited to, capsules, tablets, and aqueous suspensions and solutions. In the case of tablets for oral use, carriers which are commonly used include lactose and corn starch. Lubricating agents, such as magnesium stearate, are also typically added. For oral administration in a capsule form, useful diluents include lactose and dried corn starch. When aqueous suspensions are administered orally, the active ingredient is combined with emulsifying and suspending agents. If desired, certain sweetening and/or flavouring and/or colouring agents may be added.

The pharmaceutical compositions of this invention may also be administered in the form of suppositories for rectal administration. These compositions can be prepared by mixing a compound of this invention with a suitable non-irritating excipient which is solid at room temperature but liquid at the rectal temperature and therefore will melt in the rectum to release the active components. Such materials include, but are not limited to, cocoa butter, beeswax and polyethylene glycols.

Topical administration of the pharmaceutical compositions of this invention is especially useful when the desired treatment involves areas or organs readily accessible by topical application. For application topically to the skin, the pharmaceutical composition should be formulated with a suitable ointment containing the active components suspended or dissolved in a carrier. Carriers for topical administration of the compounds of this invention include, but are not limited to, mineral oil, liquid petroleum, white petroleum, propylene glycol, polyoxyethylene polyoxypropylene compound, emulsifying wax and water. Alternatively, the pharmaceutical composition can be formulated with a suitable lotion or cream containing the active compound suspended or dissolved in a carrier. Suitable carriers include, but are not limited to, mineral oil, sorbitan monostearate, polysorbate 60, cetyl esters wax, cetearyl alcohol, 2-octyldodecanol, benzyl alcohol and water. The pharmaceutical compositions of this invention may also be topically applied to the lower intestinal tract by rectal suppository formulation or in a suitable enema formulation. Topically-transdermal patches are also included in this invention.

The pharmaceutical compositions of this invention may be administered by nasal aerosol or inhalation. Such compositions are prepared according to techniques well-known in the art of pharmaceutical formulation and may be prepared as solutions in saline, employing benzyl alcohol or other suitable preservatives, absorption promoters to enhance bioavailability, fluorocarbons, and/or other solubilizing or dispersing agents known in the art.

The pharmaceutical composition of the invention may also comprise an additional biologically active agent. For example, where the composition is for ameliorating Duchenne muscular dystrophy, the composition may comprise an oligomer for causing exon skipping in the dystrophin gene. Such oligomers are described, for example, in U.S. application Ser. No. 12/556,626.

The oligomers of the invention are for use in therapy and, in particular, for use in inducing exon skipping during processing of myostatin pre-mRNA.

The present invention also provides a method of inducing exon skipping during processing of myostatin pre-mRNA in a patient (e.g. a human patient), the method comprising administering a therapeutically effective amount of the oligomer of the invention or the vector of the invention to the patient such that exon skipping during processing of myostatin pre-mRNA is induced.

In the above method, the oligomers can be used to increase or maintain muscle mass, or to slow the degeneration of muscle mass. In particular, musculoskeletal muscle mass can be increased or maintained, or its degeneration slowed. For example, the method can be for ameliorating muscle wasting conditions such as degenerative muscular disorders, including various forms of muscular dystrophy. Degenerative muscular disorders such as various forms of muscular dystrophies can actually be fatal at an early age of mid to late twenties. Muscle wasting conditions that can be ameliorated using the oligomers include muscular dystrophy such as Becker's muscular dystrophy, congenital muscular dystrophy, Duchenne muscular dystrophy, distal muscular dystrophy, Emery-Dreifuss muscular dystrophy, facioscapulohumeral muscular dystrophy (FSHD), limb-girdle muscular dystrophy, myotonic muscular dystrophy and oculopharyngeal muscular dystrophy. In one embodiment, the method is for ameliorating Duchenne muscular dystrophy (DMD). Other conditions that could be ameliorated by myostatin oligomers include cachexia (muscle loss due to for example, cancer, chronic obstructive pulmonary disease (COPMD) and HIV/AIDS), sarcopenia (muscle loss due to natural old age), muscle atrophy (muscle loss in denervating conditions such as motorneuron disease, and spinal muscular atrophy). In addition, myostatin knockdown by oligomers and the ensuing increased muscle bulk may also have the potential to counteract insulin-resistance in diabetes and obesity-related metabolic syndromes.

In some embodiments of the invention, another biologically active agent may also be administered in a therapeutically effective amount. For example, where the method is for ameliorating DMD, antisense oligomers for causing exon skipping in the dystrophin gene may also be administered. Such oligomers are described, for example, in U.S. application Ser. No. 12/556,626.

DETAILED DESCRIPTION OF THE INVENTION

The present invention will now be described in detail, by way of example only, with reference to the accompanying figures in which:

FIGS. 1A-1B: Bioinformatics analysis, design, and evaluation in C2C12 muscle cells of specific AOs predicted to induce skipping of myostatin exon 2. (FIG. 1A) Results from three algorithms used to identify ESE sequences for designing of exon skipping AOs targeting exon 2 of the mouse myostatin gene. The ESE Finder analysis shows the location and values above threshold for SR protein-binding motifs, SF2/ASF, SF2/ASF (BRCA 1), SC35, SRp40, and SRp55 which are shown as vertical bars above the sequence of exon 2. The Rescue ESE analysis shows the position of possible exonic splicing enhancer sites by black horizontal lines parallel to the sequence of exon 2. The PESX analysis shows the location of ESEs as light gray horizontal lines, and exon splicing silencers (ESSs) as dark gray horizontal lines. The bold horizontal laddered black lines represent the sequence of the 20-mer 2′OMePSs which were obtained after aligning the outputs from the three algorithms. (FIG. 1B) Comparison of efficacy of different 2′OMePS oligomers to induce skipping of exon 2 in myostatin mRNA from C2C12 cell cultures. RT-PCR was performed on 1 μg mRNA from C2C12 cells treated with 12 different 2′OMePS oligomers at 250 nmol/l. Transfections were performed in duplicates and the nested RT-PCR products were loaded on 1.2% agarose gel as follow: Tracks 1 and 2: oligomer A1; Tracks 3 and 4: oligomer A2; Tracks 5 and 6: oligomer A3; Tracks 9 and 10: oligomer B1; Tracks 11 and 12: oligomer B2; Tracks 13 and 14: oligomer B3; Tracks 15 and 16: oligomer C1; Tracks 17 and 18: oligomer C2; Tracks 19 and 20: oligomer C3; Tracks 23 and 24: oligomer D1; Tracks 25 and 26: oligomer D2; Tracks 27 and 28: oligomer D3; Tracks 7, 8, 21 and 22: controls with transfection reagent Lipofectamine 2000 alone, but no AO: Size Marker used is Hyper ladder IV. 2′OMePS, 2′O-methyl phosphorothioate RNA; AO, antisense oligonucleotide; bp, base pairs; ESE, exonic splicing enhancer; RT-PCR, reverse transcriptase-PCR.

FIG. 2: Antisense-induced myostatin exon 2 skipping with 2′OMePS oligomers leads to an increase in C2C12 cell proliferation. C2C12 cells were treated with a range of 2′OMePS oligomers along with lipofectamine 2000 (LF2000), and assayed 24 hours later for cell proliferation by lactic dehydrogenase assay. Treatment with 2′OMePS oligomers A3, B3, and D3 resulted in significant increases in the number of cells after 24 hours compared to the cultures treated with only transfection reagent LF2000 but no AO. C3 did not induce a substantial change. (t-test analysis, n=6; *P<0.05; **P<0.01). 2′OMePS, 2′O-methyl phosphorothioate RNA.

FIG. 3: Exon skipping in mouse following intramuscular injection of 2′OMePS oligomers targeting myostatin exon 2. Oligomers A2 and B3 (3 nmol) were administered by a single intramuscular injection into the tibialis anterior (TA) muscles of mice. Two and four weeks later, muscles were recovered, and RNA extracted and analyzed for the presence of myostatin exon 2 skipping by RT-PCR. Agarose ethidium bromide gel electrophoresis is shown for the products of RT-PCR analysis: The upper and lower bands correspond to the normal exon 1, 2, and 3 product (532 bp) and the exon 2 skipped product (158 bp), respectively which were verified by sequencing (data not shown). The faint shadow band of intermediate migration in some tracks was found upon sequencing to correspond to a product containing a partial sequence of exon 2 due to a cryptic 3′ splice site 296 nt downstream of the correct one. Tracks 1 and 2: 14 days control; Tracks 3-5: 14 days A2-treated; Tracks 6-8: 28 days A2-treated; Tracks 9-11; 14 days B3-treated; Tracks 12-14: 28 days B3-treated; Tracks 15 and 16: 28 days control. Densitometric evaluation of the skipped and unskipped bands showed that after 14 days, A2 gave 25.6% and B3 54.6% skipping, and after 28 days, A2 gave 48.6% and B3 24.5% skipping. 2′OMePS, 2′O-methyl phosphorothioate RNA; bps, base pairs; nt, nucleotides; RT-PCR, reverse transcriptase-PCR.

FIG. 4: Myostatin exon 2 skipping in C2C12 cell culture following treatment with a range of leashed-PMO lipoplexes. C2C12 cell cultures treated with a range of leashed PMOs in lipoplex form with LF2000 exhibited skipping of exon 2 in myostatin mRNA. RT-PCR was performed on 1 μg mRNA from C2C12 cells treated with 250 nmol/1 PMOs (designed on the basis of the most effective 2′OMePS sequences: A3, B3, C3, and D3) over a period of 24 hours. Transfections were performed in triplicate and RT-PCR products were loaded on 1.2% agarose gel as follows: Tracks 1-3: PMO-A; Tracks 4-6: PMO-B; Tracks 7-9: PMO C; Tracks 10-12: PMO-D; Tracks 13-15: LF2000-treated control; bps, base pairs; LP2000, lipofectamine 2000; PMO, phosphorodiamidate morpholino oligomers; RT-PCR, reverse transcriptase-PCR.

FIG. 5: Systemic injection of PMO conjugated to octa-guanidine dendrimer (Vivo-PMO) results in myostatin exon skipping associated with a significant increase in muscle mass and myofiber size. Mice were treated with 6 mg/kg of Vivo-PMO-D3 by five weekly intravenous injections, and muscles harvested for RNA extraction and immunohistology 10 days later. (a) Weight of soleus and EDL muscle after treatment. Weights of soleus muscles were significantly increased (t-test, P<0.034; n=6) whereas weights of EDL muscles showed no significant change. (b) RT-PCR was carried out on 1 μg RNA from soleus and EDL muscles and products resolved on a 1.2% agarose gel. Track 1: Vivo-PMO treated soleus; Track 2: control soleus; Track 3: Vivo-PMO treated EDL; Track 4: control EDL. (c) Distribution of myofiber sizes (CSA) in vivo-PMO treated (black bars) and control (open bars) soleus muscles. (d) Representative dystrophin immunohistology indicating increased myofibre CSA in vivo-PMO treated compared to control soleus muscle cryosections. Bar=500 μm. CSA, cross-sectional area; EDL, extensor digitorum longus; PMO, phosphorodiamidate morpholino oligomers; RT-PCR, reverse transcriptase-PCR.

INTRODUCTION

As stated above, the inventors have adopted the approach of using AOs with different chemistries, so enhancing their half-lives relative to RNAi molecules, to investigate the outcome of myostatin knockdown by exon skipping. Skipping of exon 2 (374 nucleotides) of myostatin was predicted to lead to an out-of-phase splicing of exons 1 and 3, and knockdown of myostatin due to truncation of the Open Reading Frame and nonsense-mediated mRNA decay. The data present below constitute a proof-of principle that oligonucleotide-mediated antisense exon skipping leads to a physiologically significant myostatin knockdown in vitro and in vivo. This type of antisense treatment could thus potentially form part of an effective strategy to improve various muscle-wasting conditions, and along with dystrophin rescue or augmentation, to treat Duchenne muscular dystrophy.

Example 1 Materials and Methods Bioinformatics Analysis of the Myostatin Gene to Design AOs Reagents.

Three different bioinformatics algorithms namely ESE Finder, PESX, and Rescue ESE were used to design antisense reagents. Results from the three algorithms were merged to define ESE sites and used to identify the regions of the myostatin exon 2, which are expected to be optimal targets for exon skipping antisense reagents. A set of 12 antisense reagents of 2′O-methyl RNA (2′OMePS) chemistry were designed to target four different ESE-rich regions of exon 2 of myostatin (FIG. 1A).

AO Reagents.

The 12 2′OMePS oligomers tested were obtained from Eurogentec (SA, Seraing, Belgium). The sequences of the 2′OMePS are as follows:

GDF8/A1: TCCACAGTTGGGCTTTTACT (SEQ ID NO: 20) GDF8/A2: TCTGAGATATATCCACAGTT (SEQ ID NO: 21) GDF8/A3: TCTTGACGGGTCTGAGATAT (SEQ ID NO: 22) GDF8/B1: TGATGAGTCTCAGGATTTGC (SEQ ID NO: 23) GDF8/B2: TTCATGGGTTTGATGAGTCT (SEQ ID NO: 24) GDF8/B3: TTGTACCGTCTTTCATGGGT (SEQ ID NO: 25) GDF8/C1: CAGAGATCGGATTCCAGTAT (SEQ ID NO: 26) GDF8/C2: TGTCAAGTTTCAGAGATCGG (SEQ ID NO: 27) GDF8/C3: CCTGGGCTCATGTCAAGTTT (SEQ ID NO: 28) GDF8/D1: CTGGGAAGGTTACAGCAAGA (SEQ ID NO: 29) GDF8/D2: TCTCCTGGTCCTGGGAAGGT (SEQ ID NO: 30) GDF8/D3: CAGCCCATCTTCTCCTGGTC (SEQ ID NO: 31)

PMOs were designed based on the 2′OMePS sequences. A total of four PMOs were tested and were obtained from Gene Tools (Philomath, Oreg.). PMO sequences are as follows:

Mstn A: TCTTGACGGGTCTGAGATATATCCACAGTT (SEQ ID NO: 32) Mstn B: TGTACCGTCTTTCATGGGTTTGATGAGTCT (SEQ ID NO: 33) Mstn C: CCTGGGCTCATGTCAAGTTTCAGAGATCGG (SEQ ID NO: 34) Mstn D: CAGCCCATCTTCTCCTGGTCCTGGGAAGGT (SEQ ID NO: 35)

PMOs conjugated to octa-guanidine dendrimers (so-called Vivo-PMOs) were purchased from Gene Tools.

Cell Culture and Transfection of C2C12 Cells with the Designed Antisense Reagents.

C2C12 mouse myoblasts were maintained in Dulbecco's modified Eagle's medium (Sigma-Aldrich, Poole, UK) containing 10% fetal calf serum (Sigma-Aldrich), 4 mmol/l l-glutamine, 100 U/ml penicillin and 100 μg/ml streptomycin at 37° C. and 8% CO₂. Cells were split every 24 hours to prevent differentiation. Cells were detached by incubating them with 0.15% trypsin-phosphate-buffered saline for 1 minute at 37° C., and seeded at a density of 1.5×105 cells/well of a 6-well plate. The antisense reagents of 2′OMePS chemistry were transfected at 250 nmol/1 into C2C12 cells using Lipofectamine 2000 (Invitrogen, Paisley, UK). Controls contained Lipofectamine 2000 but no antisense reagent. PMOs were leashed to complementary stretches of negatively charged DNA (obtained from MWG, Ebersberg, Germany) for efficient in vitro delivery,²⁴ using Lipofectamine 2000 as transfection reagent. All transfections were performed in Dulbecco's modified Eagle's medium containing 2 mmol/1 glutamine (without serum and antibiotics) and after 3-4 hours of transfection, the medium was replaced with full growth medium containing serum as well as antibiotics. The transfections were performed in duplicate and the experiment repeated twice.

RT-PCR Analysis of Myostatin Exon Skipping.

For in vitro experiments, 24 hours after transfection, RNA was extracted from each well using QIAshredder/RNeasy extraction kit (Qiagen, Crawley, UK). For in vivo experiments, RNA was extracted from blocks using TRIzol reagent (Invitrogen, Scotland, UK). One microgram of RNA was reverse transcribed and resulting complementary DNA amplified using specific primers obtained from MWG, using the Genescript kit (Genesys, Camberley, UK). One micro litre of PCR products obtained was used as a template for nested PCR. Sequences of the primers and details of the PCR protocols used are available on request. The products from nested PCR were separated on 1.2% agarose gel in Tris-borate/EDTA buffer and Hyper Ladder IV (Bioline, London, UK) was used as the marker. Densitometric analysis of the agarose gels was carried out using Gene Tools 3.05 (Syngene, Cambridge, UK) and percentage skipping expressed as amount of skipped product seen relative to total PCR products detected.

In Vitro Cell Proliferation Assay.

A proliferation assay using Cell Titer 96 Aqueous One Solution Cell Proliferation assay (Promega, Madison, Wis.) was performed, as reported by Cory et al.,⁷⁵ on cells transfected with different 2′OMePS. Briefly, 24 hours after seeding, the growth media was replaced with serum-free media and cells incubated at 37° C. After 24 hours of subjecting cells to serum-free media, 15 μl of assay reagent was added to 75 μl cells in a 96-well plate. Plates were read at 490 nm. Statistical analysis on the data from the proliferation assay was performed using the individual t-test.

Treatment of Mice with PMOs and Vivo-PMOs.

For all the in vivo experiments, animals (MF1 or C57B110) were bought from Harlan (Blacktown, UK) and in-house maintained, and in vivo experimentation conducted under statutory Home Office recommendation, regulatory, ethical and licensing procedures and under the Animals (Scientific Procedures) Act 1986 (project licence PPL 70/7008). For intramuscular delivery, mice were anaesthetized and injected with 3 nmol of 2′OMePS (in 25 μl normal saline) into each of the TA muscles. Control animals were injected with normal saline. Whole body weights were measured weekly. TAs of treated and control mice were excised postmortem after 2 weeks (n=4) and 4 weeks (n=4). Weights were measured and the muscles frozen in iso-pentane cooled with liquid nitrogen. For the systemic administration, C57BL10 mice were injected intravenously with 6 mg/kg of Vivo-PMO-D (Gene Tools) diluted in 200 μl of normal saline, every week for 5 weeks. Weights were measured weekly and various muscles from treated and control mice were harvested 10 days after the last injection. Cryosectioning was performed at 10 levels through the muscle.

Immunocytochemistry and Morphometry.

Hematoxylin and eosin staining was used to estimate the muscles size. For the estimation of fibre size and distribution, laminin staining was performed. Laminin antibody from Sigma-Aldrich (Dorset, UK) was used as primary antibody, with biotinylated anti-rabbit immunoglobulin G (Dako, Glostrup, Denmark) as secondary antibody. Finally sections were stained with DAB (Vector Laboratories, Burlingame, Calif.) and slides mounted in DPX (VWR International, Poole, England) after appropriate washings. Immunostaining was also carried out with Dystrophin antibody. For this, H12 Polyclonal Rabbit antibody was used as primary antibody, and Alexa fluor goat anti-rabbit 568 (fluorescein isothiocyanate) (Invitrogen, Paisley, Oreg.) was used as secondary antibody. Slides were mounted in Vectashield mounting medium with DAPI (Vector Laboratories) after appropriate washings with phosphate-buffered saline-Tween. CSA of muscle fibres was measured using SigmaScan Pro 5.0.0 (Systat Software, London, UK).

Results Bioinformatics Analysis and Design of Specific AOs Predicted to Induce Skipping of Myostatin Exon 2.

Bioinformatics analysis of exon 2 of myostatin was performed using three bioinformatics tools, ESE finder,^(27,28) PESX,^(29,30) and Rescue ESE,³¹ to identify and locate ESEs and exonic splicing suppressor or silencer motifs. The output of these algorithms is displayed in FIG. 1A. A series of overlapping AOs were designed and synthesized as 2′OMePSs and PMOs to span sequences where clusters of ESEs which were predicted by one or more of the programs coincide.

High Levels of Myostatin Exon 2 Skipping in C2C12 Cell Culture Following Treatment with a Range of AOs.

In order to verify the efficiency of these AO target sequences, C2C12 muscle cell cultures were transfected with the 2′OMePS oligomers, and nested reverse transcriptase-PCR (RT-PCR) for skipping of myostatin performed on the RNA extracted from transfected and control cells. A representative horizontal agarose gel electrophoresis separation of products obtained is shown in FIG. 1B. The level of skipping produced by each AO at 250 nmol/1 was determined semiquantitatively using densitometric analysis.³¹ All of the designed 2′OMePSs were observed to induce myostatin exon 2 skipping in C2C12 cultures but at various levels of relative efficiency. A2 and A3 induced almost 100% skipping; B3 (74%), C3 (41%), and D3 (48%) also induced a considerable level of skipping. The nature of putative antisense-induced PCR exon1-exon3 splicing product was confirmed by sequencing the products.

Antisense-Induced Myostatin Exon 2 Skipping and Myostatin Knockdown Leads to an Increase in C2C12 Cell Proliferation.

In order to verify that AO-mediated myostatin exon 2 skipping and knockdown, lead to a significant biological response, the autocrine activity of myostatin on C2C12 cell proliferation was evaluated following treatment of cultures with 2′OMePSs targeting myostatin exon 2. The cell proliferation assay was based on determination of lactic dehydrogenase activity of metabolically active cells. The results of the proliferation assay clearly showed a remarkable difference in cell proliferation in C2C12 cells treated with myostatin exon 2 AOs compared to mock-transfected control cells (FIG. 2). Statistical analysis of the data using individual paired t-tests showed that oligomers A3 (P=0.0031), B3 (P=0.0055) and D3 (P=0.0115) induced a significant increase in cell proliferation, as compared to mock transfected control cells. Oligomer C3 (P=0.0534) did not produce a statistically significant change.

Demonstration of Exon Skipping in Mouse Following Intramuscular Injection of 2′OMePS Oligomers Targeting Myostatin Exon 2.

On the basis of RT-PCR results obtained from the in-vitro studies, two 2′OMePS oligomers (A2 and B3) were selected to evaluate their ability to induce efficient exon skipping in vivo. The 2′OMePS oligomers (3 nmol) were administered by intramuscular injection into tibialis anterior (TA) muscles of mice. Two and four weeks after the injections, muscles were recovered, weighed, RNA extracted and analyzed for the presence of myostatin exon 2 skipping by RT-PCR. Both reagents (A2 and B3) induced significant level of myostatin exon 2 skipping at either the 2 weeks and 4 weeks time points after a single 2′OMePS oligomer administration (FIG. 3). Densitometric quantification of full-length and skipped product bands from the RT-PCR analyses of RNA was performed to detect which of the two 2′OMePSs tested was the more efficient in vivo. Oligomer A2 gave 25.6% skipping, and B3 gave 54.6% skipping at the 2 weeks time point. However, after 4 weeks, A2 gave 48.6% skipping whereas B3 gave 24.5% skipping. Although the skipping of myostatin exon 2 was evident, the effect was not sufficient to see a significant change in TA muscle mass (data not shown). From previous work on exon skipping for dystrophin, it is well established that the intramuscular injections of naked unconjugated AOs in undamaged muscles are not very efficient.²⁵

High Levels of Myostatin Exon 2 Skipping in C2C12 Cell Culture Following Treatment with a Range of PMOs Designed on the Basis of 2′OMePS Data.

The animal studies above established that exon skipping of the myostatin gene observed after intramuscular injection of 2′OMePS AOs was insufficient to induce change in TA mass. The PMO chemistry has been demonstrated to have very high efficiency in vivo.³³ Therefore, PMOs were designed on the basis of most efficient 2′OMePS AOs (A3, B3, C3, and D3) and initially tested in vitro. PMOs are uncharged chemicals and do not directly interact with the polycationic transfection reagent lipofectamine 2000. In order to enable reasonable transfection efficiency in C2C12 cells, PMOs were hybridized to complementary so-called leash oligonucleotides of natural negatively charged DNA chemistry as previously described.^(23,34,35) Nested RT-PCR analysis of mRNA harvested from C2C12 cells treated with leashed-PMO lipoplexes demonstrated that exon skipping was induced by all the PMOs accurate skipping of the targeted exon by both AO chemistries tested here.

Systemic Injection of PMOs Conjugated to Octa-Guanidine Dendrimer Resulted in Myostatin Exon Skipping Associated with a Significant Increase in Muscle Mass and Myofibre Size.

The conjugation of PMO with octa-guanidine dendrimer (so-called Vivo-PMOs) significantly increases the delivery and efficiency of PMO directed against exon 23 of dystrophin compared to unmodified PMO.²⁵ Therefore, a Vivo-PMO based on the sequence of the previously tested 2′OMePS oligomer, D3, was produced to evaluate systemic intravascular treatment regimes. Mice were treated with 6 mg/kg of Vivo-PMO-D3 by five weekly intravenous injections, and whole body weight and the mass of TA, soleus, and extensor digitorum longus (EDL) muscles were recorded 10 days after the last injection. Among the muscles analyzed in the treated animals the soleus showed a statistically significant change in mass (P=0.034) (FIG. 5a ). In accordance with this, high levels of exon skipping of myostatin exon 2 was demonstrated at the transcript level in soleus (79%), whereas a very low level of skipping was observed in EDL muscle (9%) (FIG. 5b ). Importantly, the cross-sectional area (CSA) of soleus muscle fibres in treated animals significantly increased (P<0.0001; mean CSA were 254±5 μm2 for control and 333±3 μm2 for PMO-treated animals (n=6) with a significant shift on the distribution of CSA (χ2=38.34; df=12) (FIG. 5c, d ). No change was observed in the CSA of EDL muscle.

Discussion

Although targeting donor splice site, acceptor splice sites and branch point sequences has successfully led to exon exclusion including DMD exon skipping^(36,38) some studies have proved that targeting splice sites does not always induce exon skipping and therefore exclusion of an exon from the pre-mRNA³⁹ These contain some consensus sequences common to many other genes; therefore there lies a possible risk of disrupting the splicing of non-specific genes⁴⁰. Exon splicing enhancers (ESEs) motifs form the binding sites for SR-protein RNA domains and thus help the splicing machinery in exon recognition⁴¹. It has been shown that intraexonic point mutations usually lead to mRNA level of exon skipping instead of misense or no change in the amino acids⁴². As SR protein binding to ESEs is very crucial for exon exclusion, blocking the ESEs with Antisense oligonucleotides (AOs) would be expected to result in exon skipping. Different software like RESCUE ESE^(43,44), ESEFinder⁴⁵ and PESX⁴⁶ have been widely used to predict possible ESE sites for different SR domains in order to assist in designing AOs^(40,47,48).

Different oligonucleotide sequences of two different chemistries to target myostatin exon 2 were designed using these available online tools which showed a promising level of exon skipping. 2′OMePS chemistry was used for the preliminary tissue culture studies because of the advantage of cheap and easy synthesis over some other the PMO chemistry^(49,50). RNA from all the C2C12 cells transfected with twelve different 2′OMePS AO sequences showed skipped myostatin exon 2 as demonstrated by RT-PCR along with the full length product. As myostatin has been established to be a negative regulator of muscle mass growth and differentiation⁵¹⁻⁵³, a decrease in its level is expected to result in enhanced proliferative capacity of muscle cells^(54,55). Therefore, a colorimetric proliferation assay based on the principle of bioreduction of a tetrazolium compound by viable cells gives a quantitative measure of living cells present in a system⁵⁶. On performing this assay on cells treated with four different AOs (one from each of the four sets based on RT PCR results), it was observed that the cells treated with AO-A3 showed increased proliferation compared to control cells (p<0.01), treatment with AOs B3 and D3 also showed an increased cell proliferation (p<0.05), whereas AO-C3 did not lead to a significant increase in level of proliferation compared to the control cells.

PMO chemistry has high nuclease resistance⁵⁷ and it does not induce RNase H-mediated downregulation of the mRNA that it targets⁵⁸. Due to uncharged background, however, PMOs cannot be delivered efficiently across cells using cationic liposomes and needs to be used at very high concentrations^(59,60). Therefore, an anionic single-stranded nucleic acid molecule called ‘leash’ was annealed to the PMO in order to mediate complex formation of PMO with the cationic transfection reagent⁶¹. Four different 20-mer 2′OMePS AO sequences were used for design and synthesis of PMOs. PMOs were 30-mers with an overlap of 10 bases between AO-2 and AO-3 of each of the 2′OMePS AO sets, A(1,2,3), B(1,2,3), C(1,2,3) and D(1,2,3). All the PMOs linked to their respective leashes resulted in induction of exon 2 skipping of myostatin mRNA and therefore showed the feasibility of the approach with two different AO chemistries.

A luciferase reporter assay has been used to study the myostatin inhibition effect of myostatin propeptide as well as that of myostatin neutralizing antibody JA16 in terms of a decrease in Smad binding to a TGF-β responsive elements called CAGA boxes^(62,64). A dose-response curve was prepared using different dilutions of recombinant mouse myostatin using human rhabdomyosarcoma cell line, A204 transfected with pGL3-(CAGA)₁₂-luc. When supernatant from C2C12 cells treated with PMO-D was assayed on the A204 cells transfected with luciferase reporter containing Smad-binding site (CAGA) and luminescence was recorded, there was found to be a significant decrease (p=0.011) in the relative light units (RLU) after 48 hours in case of supernatant from treated C2C12 cells compared to supernatant from control C2C12 cells. This indicates a decrease in the transcriptional activity of endogenous Smad proteins which are crucial for TGF-β-mediated signal transduction⁶² Therefore, inhibition of myostatin by exon skipping results in reduced biological activity related to modulation of myostatin pathway. This study thus confirms the reported results for myostatin blockade using dominant negative ActRIIB in human myoblasts⁶⁵ myostatin-neutralizing antibody, JA16⁶⁴ and myostatin propeptide⁶³ showing a decrease in Smad2 transcriptional activity and thus antagonizing biological activity. When the mean RLU values from the reporter assay for PMO-D treated cells were plotted on the myostatin standard curve, there was found to be a decrease in myostatin concentration in treated samples relative to the control cells by 44%. All these results were evident of skipping of myostatin exon 2 in vitro using two different chemistries along with modulation of proliferative capacity as well as alteration of myostatin pathway of AO-treated cells.

Further Discussion

It has been well established that myostatin is a negative regulator of skeletal muscle mass⁶⁶ and several approaches have been used to knockdown this factor to induce an increase in skeletal muscle growth.⁶⁷ The use of AOs to induce exon skipping and thereby knockdown the expression of myostatin presents several advantages over the other currently used gene therapy approaches. Firstly, there is no risk of uncontrolled insertion into the genome with AOs as in case of virus-mediated approaches.⁶⁸ Moreover, with an appropriate dosing regimen, exon skipping levels can be regulated and, if necessary the treatment can be interrupted. Importantly AOs have not been reported to produce any toxic effects or immune response so far in animal models as well as when used in clinical application.⁶⁹ Here, the inventors show that AOs of 2′OMePS chemistry, designed using bioinformatics algorithms, resulted in a substantial level of myostatin exon 2 skipping in vitro. Myostatin being an inhibitor of myogenic differentiation, controls the proliferation of myoblasts.⁷⁰ Therefore, myostatin knockdown is expected to increase the cell proliferation. The AOs designed were biologically active and induced an increase in C2C12 cell proliferation. The efficacy of knockdown by exon skipping in vivo has proved to be more challenging to establish than in vitro. The efficiency of myostatin skipping was verified by injecting 2′OMePS intramuscularly. The intramuscular treatment of a single muscle induced exon skipping, but did not appear to affect myostatin activity. This is likely to be due to supply of biologically active myostatin to the injected muscle by the bloodstream. Moreover, in a hypothetical clinical approach, the whole body should be treated. For these reasons, the inventors decided to administer the AOs by systemic tail vein injection in further experiments. PMO chemistry was chosen for this experiment due to its better stability compared to the 2′OMePS and also because PMOs have been reported to have a longer effect in vivo.⁷¹ This is particularly important for knocking down proteins like myostatin, which do not have a long half-life like dystrophin. The PMO sequence used for the systemic administration study induced efficient skipping in vitro. It also maps in a region totally conserved between mouse and human myostatin paving the way to test the same PMO for clinical applications in humans. In order to achieve a reasonable effect in undamaged muscles, a PMO conjugated to a delivery moiety has to be used.⁷² Vivo-PMO is commercially available and has been reported to be effective in normal healthy mice.²⁵ By injecting Vivo-PMO, a substantial increase in muscle size and the change of CSA fibre distribution has been obtained, but only in the soleus muscle. The differential response in EDL and soleus may be due in part to a greater amount of ActRIIb being expressed on the surface of EDL muscle, or because the intrinsic level of myostatin is greater in fast (myosin type IIb positive) myofibres.^(4,6) Alternatively, it can be speculated that the dosing regimen used, which has been reported to be optimal for Vivo-PMO for exon skipping of dystrophin gene,²⁵ does not achieve sufficient skipping of myostatin gene in EDL. In the case of dystrophin skipping, the half-life of dystrophin protein and mRNA is extremely long and therefore relatively smaller dosage of AO gives more sustained exon skipping.⁷³ However, in myostatin skipping, it is perhaps likely that more frequent redosing is required, to have a more sustained presence of AOs. This may explain the transient and weak effect in terms of whole body weight change that was observed in vivo. Interestingly, only soleus muscle showed a significant increase in weight and CSA fibre distribution. This is in compliance with some previously published data showing that soleus is the most affected muscle following a systemic approach to knockdown myostatin.⁴ The results represent a proof-of-principle that myostatin knockdown can be obtained by skipping an exon from the transcript by using AOs.

Example 2

The 30-mer PMO AOs tested above (Mstn-A to Mstn-D) were designed to target the myostatin gene in mice. Therefore, these Mstn-A to Mstn-D sequences correspond (are complementary to) to the Genbank mouse myostatin cDNA/mRNA gene sequence. The corresponding sequences complementary to the Genbank human myostatin sequences are as follows with differences between the Genbank mouse and human underlined:

Hum Mstn A: TCTCGACGGGTCTCAAATATATCCATAGTT (SEQ ID NO: 32) Hum Mstn B: TGTACCGTCTTTCATAGGTTTGATGAGTCT (SEQ ID NO: 33) Hum Mstn C: CCTGGGTTCATGTCAAGTTTCAGAGATCGG (SEQ ID NO: 34) Hum Mstn D: CAGCCCATCTTCTCCTGGTCCTGGGAAGGT (SEQ ID NO: 35)

The skipping efficiency of these AOs can be tested by transfection (leashed or unleashed: concentration between 50 and 500 nM) into cultured human myoblast cells (eg using a transfection reagent such as Lipofectamine2000™), and evaluation of skipped and unskipped mRNAs by electrophoretic densitometric analysis of RTPCR reaction products.

REFERENCES

-   1. McPherron, A C, Lawler, A M and Lee, S J (1997). Regulation of     skeletal muscle mass in mice by a new TGF-β superfamily member.     Nature 387: 83-90. -   2. Schuelke, M, Wagner, K R, Stolz, L E, Hubner, C, Riebel, T,     Kömen, W et al. 2004). Myostatin mutation associated with gross     muscle hypertrophy in a child. N Engl J Med 350: 2682-2688. -   3. Bogdanovich, S, Perkins, K J, Krag, T O, Whittemore, L A and     Khurana, T S (2005). Myostatin propeptide-mediated amelioration of     dystrophic pathophysiology. FASEB J 19: 543-549. -   4. Foster, K, Graham, I R, Otto, A, Foster, H, Trollet, C, Yaworsky,     P J et al. (2009). Adeno-associated virus-8-mediated intravenous     transfer of myostatin propeptide leads to systemic functional     improvements of slow but not fast muscle. Rejuvenation Res 12:     85-94. -   5. Qiao, C, Li, J, Jiang, J, Zhu, X, Wang, B, Li, J et al. (2008).     Myostatin propeptide gene delivery by adeno-associated virus     serotype 8 vectors enhances muscle growth and ameliorates dystrophic     phenotypes in mdx mice. Hum Gene Ther 19: 241-254. -   6. Foster, K W (2009). Eye evolution: two eyes can be better than     one. Curr Biol 19: R208-R210. -   7. Haidet, A M, Rizo, L, Handy, C, Umapathi, P, Eagle, A, Shilling,     C et al. (2008). Long-term enhancement of skeletal muscle mass and     strength by single gene administration of myostatin inhibitors. Proc     Natl Acad Sci USA 105: 4318-4322. -   8. Wagner, K R, Fleckenstein, J L, Amato, A A, Barohn, R J, Bushby,     K, Escolar, D M et al. (2008). A phase UIItrial of MYO-029 in adult     subjects with muscular dystrophy. Ann Neurol 63: 561-571. -   9. Whittemore, L A, Song, K, Li, X, Aghajanian, J, Davies, M,     Girgenrath, S et al. (2003). Inhibition of myostatin in adult mice     increases skeletal muscle mass and strength. Biochem Biophys Res     Commun 300: 965-971. -   10. Yang, Z, Zhang, J, Cong, H, Huang, Z, Sun, L, Liu, C et al.     (2008). A retrovirus-based system to stably silence GDF-8 expression     and enhance myogenic differentiation in human rhabdomyosarcoma     cells. J Gene Med 10: 825-833. -   11. Dumonceaux, J, Marie, S, Beley, C, Trollet, C, Vignaud, A,     Ferry, A et al. (2010). Combination of myostatin pathway     interference and dystrophin rescue enhances tetanic and specific     force in dystrophic mdx mice. Mol Ther 18: 881-887. -   12. Weinstein, S and Peer, D (2010). RNAi nanomedicines: challenges     and opportunities within the immune system. Nanotechnology 21:     232001. -   13. Hausen, P and Stein, H (1970). Ribonuclease H. An enzyme     degrading the RNA moiety of DNA-RNA hybrids. Eur J Biochem 14:     278-283. -   14. Zamecnik, P C and Stephenson, M L (1978). Inhibition of Rous     sarcoma virus replication and cell transformation by a specific     oligodeoxynucleotide. Proc Natl Acad Sci USA 75: 280-284. -   15. Dominski, Z and Kole, R (1993). Restoration of correct splicing     in thalassemic premRNA by antisense oligonucleotides. Proc Natl Acad     Sci USA 90: 8673-8677. -   16. Friedman, K J, Kole, J, Cohn, J A, Knowles, M R, Silverman, L M     and Kole, R (1999). Correction of aberrant splicing of the cystic     fibrosis transmembrane conductance regulator (CFTR) gene by     antisense oligonucleotides. J Biol Chem 274: 36193-36199. -   17. Sierakowska, H, Sambade, M J, Agrawal, S and Kole, R (1996).     Repair of thalassemic human β-globin mRNA in mammalian cells by     antisense oligonucleotides. Proc Natl Acad Sci USA 93: 12840-12844. -   18. Dunckley, M G, Manoharan, M, Villiet, P, Eperon, I C and     Dickson, G (1998). Modification of splicing in the dystrophin gene     in cultured Mdx muscle cells by antisense oligoribonucleotides. Hum     Mol Genet 7: 1083-1090. -   19. Cartegni, L, Chew, S L and Krainer, A R (2002). Listening to     silence and understanding nonsense: exonic mutations that affect     splicing. Nat Rev Genet 3: 285-298. -   20. Kinali, M, Arechavala-Gomeza, V, Feng, L, Cirak, S, Hunt, D,     Adkin, C et al. (2009). Local restoration of dystrophin expression     with the morpholino oligomer AVI-4658 in Duchenne muscular     dystrophy: a single-blind, placebo-controlled, dose-escalation,     proof-of-concept study. Lancet Neurol 8: 918-928. -   21. van Deutekom, J C, Janson, A A, Ginjaar, I B, Frankhuizen, W S,     Aartsma-Rus, A, Bremmer-Bout, M et al. (2007). Local dystrophin     restoration with antisense oligonucleotide PRO051. N Engl J Med 357:     2677-2686. -   22. Hudziak, R M, Barofsky, E, Barofsky, D F, Weller, D L, Huang, S     B and Weller, D D (1996). Resistance of morpholino     phosphorodiamidate oligomers to enzymatic degradation. Antisense     Nucleic Acid Drug Dev 6: 267-272. -   23. Popplewell, L J, Trollet, C, Dickson, G and Graham, I R (2009).     Design of phosphorodiamidate morpholino oligomers (PMOs) for the     induction of exon skipping of the human DMD gene. Mol Ther 17:     554-561. -   24. Gebski, B L, Errington, S J, Johnsen, R D, Fletcher, S and     Wilton, S D (2005). Terminal antisense oligonucleotide modifications     can enhance induced exon skipping. Neuromuscul Disord 15: 622-629. -   25. Wu, B, Li, Y, Morcos, P A, Doran, T J, Lu, P and Lu, Q L (2009).     Octa-guanidine morpholino restores dystrophin expression in cardiac     and skeletal muscles and ameliorates pathology in dystrophic mdx     mice. Mol Ther 17: 864-871. -   26. Jearawiriyapaisarn, N., Moulton, H. M., Sazani, P., Kole, R. &     Willis, M. S. (2010). Long-term improvement in mdx cardiomyopathy     after therapy with peptide-conjugated morpholino oligomers.     Cardiovasc Res 85, 444-453 -   27. Cartegni, L, Wang, J, Zhu, Z, Zhang, M Q and Krainer, A R     (2003). ESEfinder: A web resource to identify exonic splicing     enhancers. Nucleic Acids Res 31: 3568-3571. -   28. Smith, P J, Zhang, C, Wang, J, Chew, S L, Zhang, M Q and     Krainer, A R (2006). An increased specificity score matrix for the     prediction of SF2/ASF-specific exonic splicing enhancers. Hum Mol     Genet 15: 2490-2508. -   29. Zhang, X H and Chasin, L A (2004). Computational definition of     sequence motifs governing constitutive exon splicing. Genes Dev 18:     1241-1250. -   30. Zhang, X H, Leslie, C S and Chasin, L A (2005). Computational     searches for splicing signals. Methods 37: 292-305. -   31. Fairbrother, W G, Yeh, R F, Sharp, P A and Burge, C B (2002).     Predictive identification of exonic splicing enhancers in human     genes. Science 297: 1007-1013. -   32. Spitali, P, Heemskerk, H, Vossen, R H, Ferlini, A, den Dunnen, J     T, 't Hoen, P A et al. (2010). Accurate quantification of dystrophin     mRNA and exon skipping levels in Duchenne Muscular Dystrophy. Lab     Invest 90: 1396-1402. -   33. Alter, J, Lou, F, Rabinowitz, A, Yin, H, Rosenfeld, J, Wilton, S     D et al. (2006). Systemic delivery of morpholino oligonucleotide     restores dystrophin expression bodywide and improves dystrophic     pathology. Nat Med 12: 175-177. -   34. Popplewell, L J, Adkin, C, Arechavala-Gomeza, V, Aartsma-Rus, A,     de Winter, C L, Wilton, S D et al. (2010). Comparative analysis of     antisense oligonucleotide sequences targeting exon 53 of the human     DMD gene: Implications for future clinical trials. Neuromuscul     Disord 20: 102-110. -   35. Gebski, B L, Mann, C J, Fletcher, S and Wilton, S D (2003).     Morpholino antisense oligonucleotide induced dystrophin exon 23     skipping in mdx mouse muscle. Hum Mol Genet 12: 1801-1811. -   36. Graham, I. R., Hill, V. J., Manoharan, M., Inamati, G. B. &     Dickson, G. (2004). Towards a therapeutic inhibition of dystrophin     exon 23 splicing in mdx mouse muscle induced by antisense     oligoribonucleotides (splicomers): target sequence optimisation     using oligonucleotide arrays. Journal of Gene Medicine 6: 1149-1158. -   37. Wilton, S. D. & Fletcher, S. (2005). Antisense oligonucleotides     in the treatment of Duchenne muscular dystrophy: Where are we now?     Neuromuscul Disord 15: 399-402. -   38. Wilton, S. D., Mann, C. J., Honeyman, K., McClorey, G. &     Fletcher, S. (2002). Improved antisense oligonucleotide induced exon     skipping in the mdx mouse model of muscular dystrophy. Journal of     Gene Medicine 4: 644-654. -   39. Wilton, S. D., McClorey, G., Moulton, H. M., Iversen, P. L. &     Fletcher, S. (2006). Antisense oligonucleotide-induced exon skipping     restores dystrophin expression in vitro in a canine model of DMD.     Gene Therapy 13: 1373-1381 -   40. Aartsma-Rus, A., Heemskerk, H., de Winter, C., van Putten, M.,     Janson, A., Verschuuren, J., den Dunnen, J., van Deutekom, J. & van     Ommen, G. J. (2009). Antisense-Mediated Exon Skipping for Duchenne     Muscular Dystrophy. Human Gene Therapy 20: 660-661. -   41. Stojdl, D. F. & Bell, J. C. (1999). S R protein kinases: the     splice of life. Biochemistry and Cell Biology-Biochimie Et Biologie     Cellulaire 77: 293-298. -   42. Krainer, A. R. & Cartegni, L. (2002). Disruption of an     SF2/ASF-dependent exonic splicing enhancer in SMN2 causes spinal     muscular atrophy in the absence of SMN1. Nature Genetics 30,     377-384. -   43. Burge, C. B., Fairbrother, W. G., Yeh, R. F. & Sharp, P. A.     (2002). Predictive identification of exonic splicing enhancers in     human genes. Science 297: 1007-1013. -   44. Burge, C. B., Fairbrother, W. G., Yeo, G. W., Yeh, R.,     Goldstein, P., Mawson, M. & Sharp, P. A. (2004). RESCUE-ESE     identifies candidate exonic splicing enhancers in vertebrate exons.     Nucleic Acids Research 32: W187-W190. -   45. Krainer, A. R., Cartegni, L., Wang, J. H., Zhu, Z. W. &     Zhang, M. Q. (2003). ESEfinder: a web resource to identify exonic     splicing enhancers. Nucleic Acids Research 31: 3568-3571. -   46. Chasin, L. A. & Zhang, X. H. F. (2004). Computational definition     of sequence motifs governing constitutive exon splicing. Genes &     Development 18, 1241-1250 -   47. van Deutekom, J., Aartsma-Rus, A., Bremmer-Bout, M., Janson, A.,     den Dunnen, J. & van Ommen, G. J. (2002). Antisense-mediated exon     skipping as a gene correction therapy for Duchenne muscular     dystrophy. Journal of the Neurological Sciences 199: S75-S76. -   48. van Deutekom, J. C. & van Ommen, G. J. (2003). Advances in     Duchenne muscular dystrophy gene therapy. Nat Rev Genet 4: 774-783 -   49. Agrawal, S. (1999). Importance of nucleotide sequence and     chemical modifications of antisense oligonucleotides. Biochim     Biophys Acta 1489: 53-68. -   50. Sazani, P., Vacek, M. M. & Kole, R. (2002). Short-term and     long-term modulation of gene expression by antisense therapeutics.     Curr Opin Biotechnol 13: 468-472. -   51. Grobet, L., Martin, L. J., Poncelet, D., Pirottin, D., Brouwers,     B., Riquet, J., Schoeberlein, A., Dunner, S., Menissier, F.,     Massabanda, J., Fries, R., Hanset, R. & Georges, M. (1997). A     deletion in the bovine myostatin gene causes the double-muscled     phenotype in cattle. Nat Genet 17: 71-74. -   52. McPherron, A. C. & Lee, S. J. (1997). Double muscling in cattle     due to mutations in the myostatin gene. Proc Natl Acad Sci USA 94:     12457-12461. -   53. Szabo, G., Dallmann, G., Muller, G., Patthy, L., Soller, M. &     Varga, L. (1998). A deletion in the myostatin gene causes the     compact (Cmpt) hypermuscular mutation in mice. Mamm Genome 9:     671-672. -   54. Thomas, M., Langley, B., Berry, C., Sharma, M., Kirk, S.,     Bass, J. & Kambadur, R. (2000). Myostatin, a negative regulator of     muscle growth, functions by inhibiting myoblast proliferation. J     Biol Chem 275: 40235-40243. -   55. Zhu, X., Hadhazy, M., Wehling, M., Tidball, J. G. &     McNally, E. M. (2000). Dominant negative myostatin produces     hypertrophy without hyperplasia in muscle. FEBS Lett 474: 71-75. -   56. Berridge, M. V. & Tan, A. S. (1993). Characterization of the     cellular reduction of     3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT):     subcellular localization, substrate dependence, and involvement of     mitochondrial electron transport in MTT reduction. Arch Biochem     Biophys 303: 474-482. -   57. Summerton, J., Stein, D., Huang, S. B., Matthews, P., Weller, D.     & Partridge, M. (1997). Morpholino and phosphorothioate antisense     oligomers compared in cell-free and in-cell systems. Antisense     Nucleic Acid Drug Dev 7: 63-70. -   58. Hudziak, R. M., Barofsky, E., Barofsky, D. F., Weller, D. L.,     Huang, S. B. & Weller, D. D. (1996). Resistance of morpholino     phosphorodiamidate oligomers to enzymatic degradation. Antisense     Nucleic Acid Drug Dev 6: 267-272. -   59. Sazani, P., Kang, S. H., Maier, M. A., Wei, C., Dillman, J.,     Summerton, J., Manoharan, M. & Kole, R. (2001). Nuclear antisense     effects of neutral, anionic and cationic oligonucleotide analogs.     Nucleic Acids Res 29: 3965-3974. -   60. Suwanmanee, T., Sierakowska, H., Lacerra, G., Svasti, S., Kirby,     S., Walsh, C. E., Fucharoen, S. & Kole, R. (2002). Restoration of     human beta-globin gene expression in murine and human IVS2-654     thalassemic erythroid cells by free uptake of antisense     oligonucleotides. Mol Pharmacol 62: 545-553. -   61. Gebski, B. L., Mann, C. J., Fletcher, S. & Wilton, S. D. (2003).     Morpholino antisense oligonucleotide induced dystrophin exon 23     skipping in mdx mouse muscle. Hum Mol Genet 12: 1801-1811. -   62. Dennler, S., Itoh, S., Vivien, D., ten Dijke, P., Huet, S. &     Gauthier, J. M. (1998). Direct binding of Smad3 and Smad4 to     critical TGF beta-inducible elements in the promoter of human     plasminogen activator inhibitor-type 1 gene. EMBO J 17: 3091 3100. -   63. Thies, R. S., Chen, T., Davies, M. V., Tomkinson, K. N.,     Pearson, A. A., Shakey, Q. A. & Wolfman, N. M. (2001). GDF-8     propeptide binds to GDF-8 and antagonizes biological activity by     inhibiting GDF-8 receptor binding. Growth Factors 18:251-259. -   64. Whittemore, L. A., Song, K., Li, X., Aghajanian, J., Davies, M.,     Girgenrath, S., Hill, J. J., Jalenak, M., Kelley, P., Knight, A.,     Maylor, R., O'Hara, D., Pearson, A., Quazi, A., Ryerson, S., Tan, X.     Y., Tomkinson, K. N., Veldman, G. M., Widom, A., Wright, J. F.,     Wudyka, S., Zhao, L. & Wolfman, N. M. (2003). Inhibition of     myostatin in adult mice increases skeletal muscle mass and strength.     Biochem Biophys Res Commun 300, 965-971. -   65. Fakhfakh, R., Michaud, A. & Tremblay, J. P. (2011). Blocking the     myostatin signal with a dominant negative receptor improves the     success of human myoblast transplantation in dystrophic mice. Mol     Ther 19: 204-210. -   66. Carnac, G, Ricaud, S, Vernus, B and Bonnieu, A (2006).     Myostatin: biology and clinical relevance. Mini Rev Med Chem 6:     765-770. -   67. Patel, K and Amthor, H (2005). The function of Myostatin and     strategies of Myostatin blockade-new hope for therapies aimed at     promoting growth of skeletal muscle. Neuromuscul Disord 15: 117-126. -   68. Amantana, A and Iversen, P L (2005). Pharmacokinetics and     biodistribution of phosphorodiamidate morpholino antisense     oligomers. Curr Opin Pharmacol 5: 550-555. -   69. Arora, V, Devi, G R and Iversen, P L (2004). Neutrally charged     phosphorodiamidate morpholino antisense oligomers: uptake, efficacy     and pharmacokinetics. Curr Pharm Biotechnol 5: 431-439. -   70. Langley, B, Thomas, M, Bishop, A, Sharma, M, Gilmour, S and     Kambadur, R (2002). Myostatin inhibits myoblast differentiation by     down-regulating MyoD expression. J Biol Chem 277: 49831-49840. -   71. Iversen, P L (2001). Phosphorodiamidate morpholino oligomers:     favorable properties for sequence-specific gene inactivation. Curr     Opin Mol Ther 3: 235-238. -   72. Morcos, P A, Li, Y and Jiang, S (2008). Vivo-Morpholinos: a     non-peptide transporter delivers Morpholinos into a wide array of     mouse tissues. BioTechniques 45: 613-4, 616, 618 passim. -   73. Ghahramani Seno, M M, Graham, I R, Athanasopoulos, T, Trollet,     C, Pohlschmidt, M, Crompton, M R et al. (2008). RNAi-mediated     knockdown of dystrophin expression in adult mice does not lead to     overt muscular dystrophy pathology. Hum Mol Genet 17: 2622-2632. -   74 Paola Rimessi P, et al. Cationic PMMA Nanoparticles Bind and     Deliver Antisense Oligoribonucleotides Allowing Restoration of     Dystrophin Expression in the mdx Mouse. Molecular Therapy (2009) 17     5, 820-827 doi:10.1038/mt.2009.8) -   75. Cory, A H, Owen, T C, Barltrop, J A and Cory, J G (1991). Use of     an aqueous soluble tetrazolium/formazan assay for cell growth assays     in culture. Cancer Commun 3: 207-212. 

1. An oligomer for inducing exon skipping during processing of myostatin pre-mRNA, the oligomer comprising at least 20 contiguous bases of a base sequence selected from: 1) XCXCGACGGGXCXCAAAXAXAXCCAXAGXX; (SEQ ID NO. 1) 2) XGXACCGXCXXXCAXAGGXXXGAXGAGXCX; (SEQ ID NO. 2) 3) CCXGGGXXCAXGXCAAGXXXCAGAGAXCGG; (SEQ ID NO. 3) 4) CAGCCCAXCXXCXCCXGGXCCXGGGAAGGX; (SEQ ID NO. 4) 5) XCXXGACGGGXCXGAGAXAXAXCCACAGXX; (SEQ ID NO. 5)

6) CXGGGAAGGXXACAGCAAGA (SEQ ID NO. 17); and 7) XCXCCXGGXCCXGGGAAGGX (SEQ ID NO. 18), wherein X is T or U and the oligomer's sequence can vary from the above sequence at up to two base positions, and wherein the oligomer can bind to a target site in the myostatin pre-mRNA to cause exon skipping, wherein the oligomer is a phosphorodiamidate morpholino oligonucleotide (PMO) or a phosphorothioate-linked 2′-O-methyl oligonucleotide (2′OMePS).
 2. The oligomer of claim 1, wherein the oligomer causes an exon skipping rate of at least 40%.
 3. The oligomer of claim 1, wherein the oligomer causes an exon skipping rate of at least 90%.
 4. (canceled)
 5. The oligomer of claim 1, wherein the oligomer is a phosphorodiamidate morpholino oligonucleotide (PMO).
 6. The oligomer of claim 1, wherein the oligomer is between 20 and 40 bases in length.
 7. The oligomer of claim 1, wherein the oligomer is about 30 bases in length.
 8. The oligomer of claim 1, wherein the base sequence is selected from SEQ ID NOS. 4, 17, and
 18. 9.-11. (canceled)
 12. The oligomer of claim 1, wherein the oligomer is conjugated to or complexed with a distinct chemical entity.
 13. A vector for inducing exon skipping during processing of myostatin pre-mRNA, the vector encoding an oligomer of claim 1, wherein when the vector is introduced into a cell, the oligomer is expressed.
 14. A method of inducing exon skipping during processing of myostatin pre-mRNA in a patient, the method comprising administering a therapeutically effective amount of the oligomer of claim 1 or the vector of claim 13 to the patient such that exon skipping during processing of myostatin pre-mRNA is induced.
 15. The method of claim 14, wherein the method is for increasing or maintaining muscle mass, or slowing degeneration of muscle mass in the patient.
 16. The method of claim 14, wherein the method is for ameliorating muscle wasting conditions.
 17. The method of claim 14, wherein the method is for ameliorating a muscular dystrophy such as Becker's muscular dystrophy, congenital muscular dystrophy, Duchenne muscular dystrophy, distal muscular dystrophy, Emery-Dreifuss muscular dystrophy, facioscapulohumeral muscular dystrophy (FSHD), limb-girdle muscular dystrophy, myotonic muscular dystrophy and oculopharyngeal muscular dystrophy.
 18. The method of claim 14, wherein the method is for ameliorating Duchenne muscular dystrophy.
 19. The method of claim 18, wherein the exon skipping occurs in the dystrophin gene and which ameliorates Duchenne muscular dystrophy.
 20. The oligomer of claim 2, wherein the exon skipping rate is measured in C2C12 mouse myoblast cells after treatment with an oligomer by comparing gene expression levels of the exon in the cells to total gene expression levels in the cells.
 21. The oligomer of claim 3, wherein the exon skipping rate is measured in C2C12 mouse myoblast cells after treatment with an oligomer by comparing gene expression levels of the exon in the cells to total gene expression levels in the cells. 